Configurable constellation mapping to control spectral efficiency versus signal-to-noise ratio

ABSTRACT

Mixed mode constellation mapping to map a data block to a block of sub-carriers based on a configurable set of one or more constellation mapping schemes, and corresponding mixed mode least likelihood ratio (LLR) de-mapping based on the configurable set of one or more modulation schemes. The set may be configurable to include multiple modulation schemes to provide to a SEvSNR measure that is a non-weighted or weighted average of SEvSNR measures of the multiple modulation schemes. Mixed mode constellation mapping may be useful be configurable to control spectral efficiency versus SNR (SEvSNR) over a range of SNR with relatively fine SNR granularity, and may be configurable to control SEvSNR over a range of SNR at a fixed FEC code rate, which may include a highest available or highest permitted code rate.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. application Ser. No. 16/714,640filed Dec. 13, 2019, which is a continuation of U.S. application Ser.No. 16/177,219, filed Oct. 31, 2018, which is a continuation of U.S.application Ser. No. 15/790,807, filed Oct. 23, 2017, which is acontinuation of U.S. application Ser. No. 15/479,878, filed Apr. 5,2017, which is a continuation of U.S. application Ser. No. 14/197,208,filed Mar. 4, 2014, which claims the benefit of U.S. ProvisionalApplication No. 61/772,184, filed Mar. 4, 2013. The disclosure of eachprior application is considered part of (and is incorporated byreference in) the disclosure of this application.

TECHNICAL FIELD

Constellation mapping, modulation, least likelihood ratio (LLR)de-mapping, forward error correction (FEC), and spectral efficiencyversus signal-to-noise ratio (SNR).

BACKGROUND

Spectral efficiency refers to an information rate (i.e., excluding errorcorrection code), that may be transmitted over a given bandwidth orcommunication channel. Spectral efficiency is a measure of howefficiently a limited frequency spectrum is utilized by a physical layerprotocol (and/or by a media access control or channel access protocol).Spectral efficiency may also be referred to as spectrum efficiencyand/or bandwidth efficiency.

Modulation efficiency is measure of a gross bitrate (i.e., includingerror correction code) of a transmitted signal (e.g., in bits/second),divided by the bandwidth of the signal.

Forward error correction (FEC) may reduce a bit-error rate of atransmitted signal to permit operation at a lower signal-to-noise ratio(SNR). FEC encoding may also reduce spectral efficiency relative to anun-coded modulation efficiency. For example, a FEC code rate 1/2 reducesspectral efficiency to ½ the modulation efficiency.

An upper bound of attainable modulation efficiency is defined by theNyquist rate or Hartley's law. An upper bound for spectral efficiencywithout bit errors in a channel at a given SNR is defined by the Shannonor Shannon-Hartley theorem.

Conventional standards for cable modems specify multiple FEC blocksizes, FEC code rates, and quadrature amplitude modulation (QAM)constellations. For a given FEC block size and code rate, each QAMconstellation provides an acceptable BER above a SNR threshold.

Conventionally, spectral efficiency versus SNR (SEvSNR) is controllablethrough selectable FEC code rates. Supporting multiple code ratesincreases system complexity. In addition, lower code rates reduceefficiency in terms of low-density parity-check (LDPC) encoder/decoderiterations.

SUMMARY

Disclosed herein configurable constellation mapping techniques, referredto herein as mixed mode constellation mapping, to map a data block to ablock of sub-carriers based on a configurable set of one or moreselectable constellation mapping schemes. The terms constellationmapping scheme and modulation scheme are used interchangeably herein.

Also disclosed herein corresponding configurable LLR de-mappingtechniques, referred to herein as mixed mode LLR de-mapping.

Mixed mode constellation mapping may be configurable to control spectralefficiency versus SNR (SEvSNR) over a range of SNR, and may beconfigured to control SEvSNR with relatively fine SNR granularity.

Mixed mode constellation mapping may be configurable to control SEvSNRat a fixed FEC code rate, which may reduce system complexity.

Mixed mode constellation mapping may be configurable to control SEvSNRat a highest available FEC code rate, which may improve LDPC iterationefficiency relative to a system that controls SEvSNR with changes to aFEC code rate.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of a mixed modulation constellation mapperconstellation mapper to map a data block to a block of sub-carriersbased on a configurable set of one or more constellation mappingschemes.

FIG. 2 is a block diagram of a transceiver that includes a mixed modeconstellation mapper within a transmit path, and a mixed mode leastlikelihood ratio (LLR) de-mapper within a receive path.

FIG. 3 is a block diagram of a block encoder that includes a BCH outerencoder and a low-density parity-check (LDPC) inner encoder.

FIG. 4 is a block diagram of a transmit path that includes a mixed modeconstellation mapper to modulate segments of a block-encoded bit streamto a block of sub-carriers based on a configurable set of one of moreselectable modulation schemes.

FIG. 5 is a block diagram of a mixed mode constellation mapper to mapsegments of a block-encoded bit stream to a block of sub-carriers basedon a mix of first and second modulation schemes M1 and M2.

FIG. 6 is a depiction in which sub-carriers C are modulated withsegments S based on alternating modulation schemes M1 and M2.

FIG. 7 is a chart of bit error rate (BER) versus signal-to-noise ratio(SNR) for non-square and mixed modulation schemes based on simulations.

FIG. 8 is a spectral efficiency plot for the modulation schemes of FIG.7, based on an SNR requirement measured at BER 1e-8 in FIG. 7.

FIG. 9 is a block diagram of a computer system configured to mapsegments of a bit stream over a block of sub-carriers based on aconfigurable set of one or more selectable modulation schemes, and tode-map a block of sub-carriers based on the configurable set of one ormore modulation schemes.

FIG. 10 is a block diagram of a system that includes a processor andmemory, and a communication system that includes a mixed modeconstellation mapper and a mixed mode LLR de-mapper.

FIG. 11 is a flowchart of a method of mapping and de-mapping blocks ofsub-carriers based on a configurable set of one or more modulationschemes.

In the drawings, the leftmost digit(s) of a reference number identifiesthe drawing in which the reference number first appears.

DETAILED DESCRIPTION

FIG. 1 is a block diagram of a mixed modulation constellation mapperconstellation mapper 100 to map a data block to a block of sub-carriersbased on a configurable set of one or more constellation mappingschemes.

Mixed mode constellation mapper 100 includes multiple constellationmappers 102, each to map segments of a bit stream 104 based on arespective one of multiple modulation schemes.

For illustrative purposes, constellation mappers 102 are illustratedhere as quadrature amplitude modulation (QAM) constellation mappers,each to map segments of bit stream based on a respective one of multipleQAM constellations. Mixed mode constellation mapper 100 is not, however,limited to QAM constellation mappers.

Constellation mappers 102 may be configured to map segments of bitstream 104 as symbols of respective sub-carriers 112.

Constellation mappers 102 may each be configured to map a sequence ofsegments of bit stream 104 into a base-band modulated sequence ofcomplex symbols (e.g., phase and amplitude data), to providesub-carriers 112 as frequency domain sub-carriers.

Constellation mappers 102 may be configured to map segments of bitstream 104 in parallel with one another.

One or more of constellation mappers 102 may represent multiplesimilarly configured constellation mappers.

One or more constellation mappers 102 may be configured to map tonon-square QAM constellations. This may improve SNR resolution (i.e.,reduce step-size) along an SNR axis of a spectral efficiency versus SNR(SEvSNR) graph.

Constellation mapper 100 further includes an inverse multiplexer 106 toapportion segments of bit stream 104 amongst selectable ones ofconstellation mappers 102. Inverse multiplexer 106 may be controllableand/or programmable to provide segments of bit stream 104 to selectableones of constellation mappers 102.

Example selectable configurations mixed mode constellation mapper 100are provided in Table 1 below.

TABLE 1 Configuration Constellation Constellation Mapping/ ReferenceMapper(s) Modulation Scheme(s) CR1 102-1 QAM4096 CR2 102-1, 102-2QAM4096, QAM2048 CR3 102-2 QAM2048 CR4 102-2, 102-3 QAM2048, QAM1024 CR5102-3 QAM1024 CR6 102-3, 102-4 QAM1024, QAM512 CR7 102-4 QAM512 CR8102-4, 102-5 QAM512, QAM256 CR9 102-5 QAM256 CR10 102-5, 102-6 QAM256,QAM128 CR11 102-6 QAM128

Methods and systems disclosed herein are not limited to the exampleconfigurations of Table 1.

For example, mixed mode constellation mapper 100 may be configurable tomap segments of bit stream 104 to a block of sub-carriers with a mix orcombination of more than two modulation schemes.

As another example, mixed mode constellation mapper 100 may include oneor more other selectable combinations of modulation schemes (e.g., acombination of constellation mappers 102-1 and 102-6 to map segments ofbit stream 104 over a mix of QAM4096 sub-carriers and QAM128sub-carriers).

As another example, a selectable set of multiple modulation schemes maybe configured to map to approximately equal numbers of sub-carriers ofeach of multiple modulation schemes (i.e., a mix of 50% QAM4096sub-carriers and 50% QAM2048 sub-carriers), or unequal numbers (e.g., amix of 25% QAM4096 carriers and 75% QAM2048 sub-carriers). Inversemultiplexer 106 may be controllable and/or programmable to adjust aratio of sub-carriers of multiple modulation schemes.

Inverse multiplexer 106 may be further controllable and/or programmableto segment bit stream 104 in bit-lengths that are based on modulationschemes of respective constellation mappers 102. For example, a2048-point QAM constellation (QAM2048) has 2048=2¹¹ constellationpoints, each associated with a respective 11-bit codeword. Inversemultiplexer 106 may be configured to apportion 11-bit segments toQAM2048 constellation mapper 102-2 in FIG. 1.

Constellation mapper 100 further includes a control block 108 toconfigure and/or program inverse multiplexer 106 to provide segments ofbit stream 104 to selectable ones of constellation mappers 102. Controlblock 108 may be further configured to control inverse multiplexer 106to segment bit stream 104 based on a selected set of one or moreconstellation mappers 102. Control block 108 may be further configuredto control inverse multiplexer 106 to adjust a ratio of sub-carriers ofmultiple modulation schemes.

Sub-carriers 112 may be provided to a modulator to modulate a carrier,such as described below with reference to FIG. 2.

Mixed mode constellation mapper 100 may be configurable to controlSEvSNR of the modulated carrier with relatively fine SNR granularity. InTable 1, for example, configuration CR2 (a mix of QAM4096 and QAM2048),may be selected to provide a SEvSNR measure that is between SEvSNRmeasures of QAM4096 and QAM2048. A proportion of QAM4096 sub-carriers toQAM2048 sub-carriers may be configured to provide configuration CR2 witha SEvSNR measure that is a non-weighted or a weighted average the SEvSNRmeasures of QAM4096 and QAM2048.

Mixed mode constellation mapper 100 may be useful control a SEvSNR ofthe modulated carrier within relatively fine SNR granularity, whilemaintaining a fixed FEC code rate and/or a highest available FEC coderate, such as described below with reference to FIG. 2.

FIG. 2 is a block diagram of a transceiver 200 that includes a mixedmode constellation mapper 218 within a transmit path 202. Mixed modeconstellation mapper 218 may be configured as described above withrespect to FIG. 1. Mixed mode constellation mapper 218 is not, however,limited to the example of FIG. 1.

Transceiver 200 further includes a mixed mode least likelihood ratio(LLR) de-mapper 236 within a receive path 108, which is describedfurther below.

Transceiver 200 may be referred to herein as a modulator/demodulator ormodem 200, and may be configured as a cable modem. Transceiver 200 isnot, however, limited cable modems.

Transmit path 202 further includes a block encoder 214 to block-encode abit stream 206, to provide a block-encoded bit stream 216. Block encoder214 may include, without limitation, a forward error correction (FEC)block encoder, such as described below with reference to FIG. 3. In FIG.2, block-encoded bit stream 216 is illustrated as an FEC (e.g., LDPC)block-encoded bit stream. Block encoder 214 is not, however, limited toan FEC block encoder, an LDPC FEC block encoder, or to the examples ofFIG. 3.

FIG. 3 is a block diagram of a block encoder 300 to block-encode a bitstream 306 to provide a block-encoded bit stream 316. Block encoder 300includes a BCH encoder 320 and a low-density parity-check (LDPC) encoder322. The acronym BCH is based on names of mathematicians AlexisHocquenghem, Raj Bose, and D. K. Ray-Chaudhuri.

LDPC encoder 322 may be configured as an inner error correction encoderand BCH encoder 320 may be configured as outer error correction encoder.

Block encoder 300 further includes a bit interleave or scramble block324, such as to perform (e.g., parity interleaving and/or column-twistinterleaving).

In FIG. 2, mixed mode constellation mapper 218 is configurable to mapsegments of block-encoded bit stream 216 to a block of sub-carriers 224based on a set of one of more selectable modulation schemes, such asdescribed above with respect to FIG. 1.

Mixed mode constellation mapper 218 may be configured to map a singleFEC-encoded data block over a block of sub-carriers 224, multipleFEC-encoded data blocks over a block of sub-carriers 224, and/or aportion of an FEC-encoded data block over a block of sub-carriers 224.

As described above with respect to FIG. 1 and Table 1, mixed modeconstellation mapper 218 may be configured to control SEvSNR of amodulated passband carrier 204 over a range of SNR with relatively fineSNR granularity.

Mixed mode constellation mapper 218 may be configured to control SEvSNRof modulated passband carrier 204 over a range of SNR with relativelyfine SNR granularity while maintaining a fixed FEC code rate and/orwhile using a highest available or highest permissible FEC code rate. Ahighest permissible FEC code rate may be defined by a standard.

In FIG. 3, for example, LDPC encoder 322 may be configured to encodeblock lengths of 16,200 bits with a selectable code rate 4/9, 6/3,11/15, 7/9, or 37/45, or 8/9. In this example, LDPC encoder 322 may beset to use the highest available code rate 8/9, and SEvSNR may becontrolled with mixed mode constellation mapper 218 in FIG. 2. Furtherin this example, BCH encoder 320 may be configured to encode blocksusing an outer 12-bit error correcting BCH code with 168 parity bits.LDPC encoder 322 and BCH encoder 320 are not, however, limited to theseexamples.

In FIG. 2, transmit path 202 further includes a modulator 228 tomodulate a baseband carrier 230 with sub-carriers 224. Modulator 228 maybe configured to perform orthogonal frequency division multiplexing(OFDM), orthogonal frequency division multiple access (OFDMA), and/orsingle-carrier frequency division multiple access (SC-FDMA). In aSC-FDMA configuration, modulator 228 may be configured to receivemodulated sub-carriers from one or more other constellation mappers tocombine with sub-carriers 224. Modulator 228 is not, however, limited tothese examples.

Modulator 228 may include an Inverse Fast Fourier Transform (IFFT)module 227 to convert frequency domain sub-carriers 124 to time domainsamples 129. In a SC-FDMA configuration, modulator 228 may include oneor more additional IFFT modules to convert frequency domain sub-carriersfrom one or more other constellation mappers to time domain samples.

IFFT module 227 may be configured to compute an IFFT for each of FECencoded block of bit stream 116. In this example, unused inputs to IFFTmodule 227 may be zero-padded. In another embodiment, modulator 228 isconfigured to collect sub-carriers 224 until there are sufficientsub-carriers 224 for all inputs of IFFT module 227. Each IFFTcomputation may represent a symbol of modulated baseband carrier 230.

Modulator 228 further includes a digital-to-analog converter (DAC) 231to convert time domain samples 229 to provide modulated baseband carrier130 as an analog signal.

Transmit path 202 further includes a frequency converter 232 to convertcarrier 130 from baseband to a pass-band (e.g., to a radio frequency orRF), modulated carrier 204.

Transmit path 202 may include one or more additional blocks to performone or more additional operations or functions such as, withoutlimitation, pilot insertion, interleaving, cyclic prefix insertion,and/or windowing, such as described below with reference to FIG. 4.Transmit path 202 is not, however, limited to the example of FIG. 4.

FIG. 4 is a block diagram of a transmit path 400 that includes a mixedmode constellation mapper 402 to modulate segments of a block-encodedbit stream 416 to a block of sub-carriers 403 based on a configurableset of one of more modulation schemes, such as described above withrespect to FIG. 1.

Transmit path 400 further includes a framer/interleaver 404 to addpilots to sub-carriers 403 and to interleave the sub-carriers in timeand/or frequency. Framer/interleaver 404 may be configured, withoutlimitation, as an OFDM framer/interleaver or an orthogonal frequencydivision multiple access (OFDMA) framer/interleaver.

Transmit path 400 further includes a pre-equalizer 406 to pre-distortthe constellation symbols to compensate for a channel responseassociated with a transmission channel.

Transmit path 400 further includes an IFFT module 408 to transform eachpre-equalized symbol from pre-equalizer 406 into the time domain, and toconvert IFFT results from parallel to serial.

Transmit path 400 may be configured to zero-pad unused inputs to IFFTmodule 408. Alternatively, modulator 400 may be configured to collectoutputs of pre-equalizer 406 until there are sub-carriers for all inputsto IFFT module 408.

Transmit path 400 further includes a cyclic prefix (CP) and windowingblock 410 to prepend a cyclic prefix and to perform a windowingoperation.

Transmit path 400 further includes a DAC 412, such as described abovewith respect to DAC 231 in FIG. 2.

FIG. 5 is a block diagram of a mixed mode constellation mapper 500 tomap segments of a block-encoded bit stream 516 to a block ofsub-carriers 524 based on a mix of first and second modulation schemesM1 and M2.

Mixed modulation constellation mapper 500 includes first and secondconstellation mappers 522-1 and 522-2. First constellation mapper 522-1is configured to map based on a first modulation scheme, denoted here asM1. Second constellation mapper 522-2 is configured to map based on asecond modulation scheme, denoted here as M2. First constellation mapper522-1 and/or second constellation mapper 522-2 may represent multiplesimilarly configured constellation mappers.

In an embodiment, mixed mode constellation mapper 500 is configuredapportion segments S of block encoded bit stream 516 amongstconstellation mappers 522-1 and 522-2 to modulate equal or nearlynumbers of M1 and M2 sub-carriers. This may be useful to provide aSEvSNR measure that is a non-weighted average of SEvSNR measures ofmodulation schemes M1 and M1.

In another embodiment, mixed mode constellation mapper 500 is configuredapportion segments S of block encoded bit stream 516 amongst first andsecond constellation mappers 522-1 and 522-2 to modulate unequal numbersof M1 and M2 sub-carriers. This may be useful to provide a SEvSNRmeasure that is a weighted average of SEvSNR measures of modulationschemes M1 and M1.

An example is provided in Table 2 below in which segments S areapportioned amongst first and second constellation mappers 422-1 and422-2 in an alternating fashion to modulate equal or nearly numbers ofM1 and M2 sub-carriers. FIG. 6 is a corresponding depiction 600 in whichsub-carriers C are modulated with segments S based on alternatingmodulation schemes M1 and M2. One or more other configurations may beemployed to modulate a block across equal or nearly equal numbers of M1and M2 sub-carriers.

TABLE 2 Constellation Modulation Segment Mapper Sub-Carrier Scheme S1522-1 C1 M1 S2 522-2 C2 M2 S3 522-1 C3 M1 S4 522-2 C4 M2 . . . . . . . .. . . .

Receive path 208 of FIG. 2 is now described.

Receive path 208 includes a frequency converter 234 to convert pass-bandmodulated carrier 212 to baseband, illustrated here as a modulatedbaseband carrier 235.

Receive path 208 further includes a demodulator 237 to demodulatesub-carriers 244 of modulated baseband carrier 235. In FIG. 2,demodulator 237 includes an analog-to-digital converter (ADC) 238 toprovide time domain samples 240 of baseband carrier 235. Demodulator 237further includes a Fast Fourier Transform (FFT) module 242 to converttime domain samples 240 to frequency domain sub-carriers 244. In aSC-FDMA configuration, demodulator 237 may include one or moreadditional FFT modules.

Mixed mode LLR de-mapper 236 is configured to compute LLRs 248 for ablock of demodulated sub-carriers 244 based a set of one or moremodulation schemes. Mixed mode LLR de-mapper may be configurable withrespect to the set of one or more modulation schemes, and may beconfigured based on a configuration of mixed mode constellation mapper218.

Mixed mode LLR de-mapper 236 is configured to compute an LLR for eachbit of each codeword of each sub-carrier within the block of demodulatedsub-carrier 244. In FIG. 2, mixed mode LLR de-mapper 236 includes LLRde-mappers 246-1 through 246-i, each to compute respective LLRs 248based on a respective one of multiple modulation schemes. For example,if LLR de-mapper 246-1 is configured based on QAM2048, it will compute aset of LRRs 248-1 to include 11 LLRs for codeword or symbol of asub-carrier assigned to de-mapper 246-1.

Each LLR de-mapper 246 may be configured to processes one sub-carrier ofa symbol at a time.

Each LLR de-mapper 246 may include a corresponding LLR de-interleaver tooperate on respective LLRs.

Receive path 208 further includes a block decoder 254 to decode bitstream 210 based on LLRs 248. Block decoder 254 may be configured basedon a configuration of block encoder 214. Block decoder 254 may include,without limitation, a FEC block decoder, which may include a BCH outerdecoder, a LDPC inner decoder, and/or a bit de-interleaver, and whichmay be configured to in a reverse order relative to block encoder 214.

Simulations have been performed to determine bit error rates fornon-square and 50% mixed modulation schemes based on LDPC FEC blocks of16,200 bits, code rate 8/9, and an outer 12-bit-error correcting BCHcode with 168 parity bits. Results of the simulations are describedbelow with reference to FIGS. 7 and 8. Methods and systems disclosedherein are not, however, limited to the simulations.

For QAM4096 OFDM sub-carrier modulation, spectral efficiency of the FECis 10.54 bits/s/Hz. The AWGN SNR needed to achieve a BER of 1e-8 is 35.2dB. For QAM2048 OFDM sub-carrier modulation, spectral efficiency of theFEC is 9.67 bits/s/Hz, and the AWGN SNR needed to achieve a BER of 1e-8is 32.3 dB.

FIG. 7 is a chart of bit error rate (BER) versus SNR for non-square and50% mixed modulation schemes based on simulations under the conditionsspecified above.

QAM2048 is represented in a graph 702.

QAM4096 is represented in a graph 704.

A 50% mix of QAM2048 and QAM4096 is represented in a graph 706. This hasa spectral efficiency of 10.1 bis/s/Hz, which is halfway between QAM2048and QAM4096, and the AWGN SNR needed to achieve a BER of 1e-8 is about33.9 which is approximately halfway between the SNRs required forQAM4096 and QAM2048.

FIG. 8 is a spectral efficiency plot 800 for the modulation schemes ofFIG. 7, based on an SNR requirement measured at BER 1e-8 in FIG. 7. Plot800 is based on the simulations under the conditions specified above.

In FIG. 8, performance points of the modulation schemes line up in asubstantially linear line about 3 dB from Shannon channel capacity.

Performance point 802 corresponds to QAM2048.

Performance point 804 corresponds to QAM4096.

Performance point 806 corresponds to a 50% mix of QAM2048 and QAM4096.

The simulations show that modulation of encoded blocks over equalnumbers of QAQ2048 and QAM4096 sub-carriers under the conditionsspecified above provides an OFDM carrier with a spectral efficiency of10.10 bits/s/Hz, which is an average of the spectral efficiencies ofQAM2048 (i.e., 10.54 bits/s/Hz) and QAM4096 (i.e., 9.67 bits/s/Hz).

Spectral efficiency plot 800 shows that multiple selectable modulationconfigurations provide relatively fine resolution along the SNR axis(approximately 1.5 dB SNR in the example of FIG. 8).

One or more features disclosed herein may be implemented in, withoutlimitation, circuitry, a machine, a computer system, a processor andmemory, a computer program encoded within a computer-readable medium,and/or combinations thereof. Circuitry may include discrete and/orintegrated circuitry, application specific integrated circuitry (ASIC),a system-on-a-chip (SOC), and combinations thereof. Informationprocessing by software may be concretely realized by using hardwareresources.

FIG. 9 is a block diagram of a computer system 900 configured to mapsegments of a bit stream over a block of sub-carriers based on aconfigurable set of one or more selectable modulation schemes, and tode-map a block of sub-carriers based on the configurable set ofmodulation scheme(s).

Computer system 900 includes one or more processors, illustrated here asa processor 902, to execute instructions of a computer program 906encoded within a computer readable medium 904.

Processor 902 may include one or more instruction processors and/orprocessor cores, and may include a microprocessor, a graphics processor,a physics processor, a digital signal processor, a network processor, afront-end communications processor, a co-processor, a management engine(ME), a controller or microcontroller, a central processing unit (CPU),a general purpose instruction processor, and/or an application-specificprocessor.

Processor 902 may further include a control unit to interface betweenthe instruction processor(s)/core(s) and computer readable medium 904.

Computer readable medium 904 may include a transitory or non-transitorycomputer-readable medium, and may include, without limitation,registers, cache, and/or memory.

Computer-readable medium 904 may include data 908 to be used byprocessor 902 during execution of computer program 906 and/or generatedby processor 902 during execution of computer program 906.

In the example of FIG. 9, computer program 906 includes transceiverinstructions 914 to cause processor 902 to perform one or moretransceiver functions, such as described in one or more examples herein.

Transceiver instructions 914 include mixed mode constellation mappinginstructions 916 to cause processor 902 to perform one or more mixedmode constellation mapping functions, such as described in one or moreexamples herein.

Transceiver instructions 914 further include mixed mode LLR de-mappinginstructions 918 to cause processor 902 to perform one or more mixedmode LLR de-mapping functions, such as described in one or more examplesherein.

Computer program 906 may further includes baseband and/or dataprocessing instructions 924 to cause processor 902 to perform one ormore baseband signal processing functions and/or data processingfunctions.

Computer system 900 further includes communications infrastructure 940to communicate amongst devices and/or resources of computer system 900.

Computer system 900 further includes one or more input/output (I/O)devices and/or controllers 942 to interface with one or more othersystems, such as a communication channel or medium.

Methods and systems disclosed herein may be implemented with respect toone or more of a variety of systems, such as described below withreference to FIG. 10. Methods and systems disclosed herein are not,however, limited to the examples of FIG. 10.

FIG. 10 is a block diagram of a system 1000, including a processor 1002and memory, cache, registers, and/or other computer-readable medium,collectively referred to herein as memory 1004. System 1000 furtherincludes a communication system 1006 and a user interface system 1030.System 1000 may further include an electronic or computer-readablestorage medium (storage) 1040, which may be accessible to processor1002, communication system 1006, and/or user interface system 1030.

Communication system 1006 may include a mixed modulation constellationmapper and/or a mixed modulation LLR de-mapper, such as described in oneor examples herein.

Communication system 1006 may be configured to communicate with anexternal communication network on behalf of processor 1002 and/or userinterface system 1030. The external network may include a voice network(e.g., a wireless telephone network), and/or a data or packet-basednetwork (e.g., a proprietary network and/or the Internet), such as adigital video broadcast (e.g., over cable) network.

Communication system 1006 may include a wired (e.g., cable) and/orwireless communication system, and may be configured in accordance withone or more digital video broadcast standards.

User interface system 1030 may include a monitor or display 1032 and/ora human interface device (HID) 1034. HID 1034 may include, withoutlimitation, a key board, a cursor device, a touch-sensitive device, amotion and/or image sensor, a physical device and/or a virtual device,such as a monitor-displayed virtual keyboard. User interface system 1030may include an audio system 1036, which may include a microphone and/ora speaker.

System 1000 and/or communication system 1006 may be configured as astationary or portable/hand-held system, and may be configured as, forexample, a mobile telephone, a set-top box, a gaming device, and/or arack-mountable, desk-top, lap-top, notebook, net-book, note-pad, ortablet system, and/or other conventional and/or future-developedsystem(s). System 1000 is not, however, limited to these examples.

System 1000 or portions thereof may be implemented within one or moreintegrated circuit dies, and may be implemented as a system-on-a-chip(SoC).

FIG. 11 is a flowchart of a method 1100 of mapping and de-mapping blocksof sub-carriers based on a configurable set of one or more modulationschemes.

At 1102, a data block is mapped to a block of sub-carriers based on aconfigurable set of one or more modulation schemes to manage SEvSNR,such as described in one or more examples herein.

At 1104, LLRs are computed for a block of demodulated sub-carriers basedon the configurable set of one or more modulation schemes, such asdescribed in one or more examples herein.

EXAMPLES

The following examples pertain to further embodiments.

An Example 1 is a method that includes mapping a data block to a blockof sub-carriers based on a set of one or more modulation schemes, andconfiguring the set of one or more modulation schemes to controlspectral efficiency versus signal-to-noise ratio (SEvSNR) of over arange of SNR.

In an Example 2, the method further includes configuring the set toinclude multiple modulation schemes to provide a SEvSNR measure that isan average of SEvSNR measures of the multiple modulation schemes.

In an Example 3, the method further includes configuring the set toinclude multiple modulation schemes to provide a SEvSNR measure that isa non-weighted average of SEvSNR measures of the multiple modulationschemes.

In an Example 4, the method further includes configuring the set toinclude multiple modulation schemes to provide a SEvSNR measure that isa weighted average of SEvSNR measures of the multiple modulationschemes.

In an Example 5, the method further includes configuring a ratio ofsub-carriers of the multiple modulation schemes to control the SEvSNRmeasure over a range SNR.

In an Example 6, the method further includes configuring the set includeone of a first modulation scheme to provide a first SEvSNR measure, asecond modulation scheme to provide a second SEvSNR measure, and acombination of the first and second modulation schemes to provide athird SEvSNR measure that is between the first and second SEvSNRmeasures.

In an Example 7, the method further includes configuring the set toinclude one or more of multiple quadrature amplitude modulation (QAM)schemes, each associated with a respective constellation map.

In an Example 8, the method further includes block-encoding a bit streamwith a forward error correction (FEC) to provide a FEC-encoded datablock, mapping the FEC-encoded data block to the block of sub-carriers,and manage the set to control SEvSNR over a range of SNR at a fixed FECcode rate.

In an Example 9, the method further includes FEC encoding at a highestone of multiple selectable code rates.

In an Example 10, the FEC encoding includes low-density parity-check(LDPC) inner encoding to block-encode with a code rate 8/9, and BCHouter encoding to block-encode with an outer 12-bit error correcting BCHcode and 168 parity bits. Example 10 further includes configuring theset to include one or more of multiple non-square quadrature amplitudemodulation (QAM) schemes.

In an Example 11, further to Example 10, the method further includescontrolling the SEvSNR over a range of SNR in increments of 1.5 dB SNR.

An Example 12 is a one machine readable medium comprising a plurality ofinstructions that in response to being executed on a computing device,cause the computing device to carry out a method according to any one ofclaims 1-11.

An Example 13 is a communications device arranged to perform the methodof any one of Examples 1-11.

An Example 14 is an apparatus to compute a device location, configuredto perform the method of any one of the claims 1-11.

An Example 15 is a computer system to perform the method of any ofclaims 1-11.

An Example 16 is a machine to perform the method of any of claims 1-11.

An Example 17 is an apparatus comprising: means for performing themethod of any one of claims 1-11.

An Example 18 is a computing device comprising a chipset according toany one of the claims 1-11.

Methods and systems are disclosed herein with the aid of functionalbuilding blocks illustrating functions, features, and relationshipsthereof. At least some of the boundaries of these functional buildingblocks have been arbitrarily defined herein for the convenience of thedescription. Alternate boundaries may be defined so long as thespecified functions and relationships thereof are appropriatelyperformed. While various embodiments are disclosed herein, it should beunderstood that they are presented as examples. The scope of the claimsshould not be limited by any of the example embodiments disclosedherein.

1-33. (canceled)
 34. A cable modem apparatus, comprising: circuitry toremove a cyclic prefix (CP) and to perform a reverse windowing operationon time domain constellation symbols of mixed-modulation datasub-carriers, wherein the data sub-carriers include Orthogonal FrequencyDivision Multiplexing (OFDM) sub-carriers and are modulated based onQuadrature Amplitude Modulation (QAM) constellations including a squareQAM constellation and a non-square QAM constellation; a FourierTransform module to transform the constellation symbols from time domainsymbols to frequency domain symbols; an de-interleaver to de-interleavethe constellation symbols in time and frequency; a demodulator todemodulate the sub-carriers; and a constellation demapper to demap thesub-carriers.
 35. The apparatus of claim 34, wherein the constellationdemapper to demap unequal numbers of the sub-carriers as between thesquare QAM constellation and the non-square QAM constellation.
 36. Theapparatus of claim 34, wherein the non-square QAM constellation isselected from the group consisting of 128, 512 QAM constellations and a2048 QAM constellation.
 37. The apparatus of claim 36, wherein thesquare QAM constellation is selected from the group consisting of 16,64, 256, 1024 QAM constellations and a 4096 QAM constellation.
 38. Asystem including: a wireless communication system to communicate with anexternal communication network; circuitry to remove a cyclic prefix (CP)and to perform a reverse windowing operation on time domainconstellation symbols of mixed-modulation data sub-carriers, wherein thedata sub-carriers include Orthogonal Frequency Division Multiplexing(OFDM) sub-carriers and are modulated based on Quadrature AmplitudeModulation (QAM) constellations including a square QAM constellation anda non-square QAM constellation; a Fourier Transform module to transformthe constellation symbols from time domain symbols to frequency domainsymbols; an de-interleaver to de-interleave the constellation symbols intime and frequency; a demodulator to demodulate the sub-carriers; and aconstellation demapper to demap the sub-carriers.
 39. The system ofclaim 38, wherein the constellation demapper to demap unequal numbers ofthe sub-carriers as between the square QAM constellation and thenon-square QAM constellation.
 40. The system of claim 38, wherein thenon-square QAM constellation is selected from the group consisting of128, 512 QAM constellations and a 2048 QAM constellation.
 41. The systemof claim 40, wherein the square QAM constellation is selected from thegroup consisting of 16, 64, 256, 1024 QAM constellations and a 4096 QAMconstellation.
 42. A method to be used at a cable modem apparatusincluding: removing a cyclic prefix (CP) and to perform a reversewindowing operation on time domain constellation symbols ofmixed-modulation data sub-carriers, wherein the data sub-carriersinclude Orthogonal Frequency Division Multiplexing (OFDM) sub-carriersand are modulated based on Quadrature Amplitude Modulation (QAM)constellations including a square QAM constellation and a non-square QAMconstellation; transforming the constellation symbols from time domainsymbols to frequency domain symbols; de-interleaving the constellationsymbols in time and frequency; demodulating the sub-carriers; and usinga constellation demapper to demap the sub-carriers.
 43. The method ofclaim 42, wherein demapping includes demapping unequal numbers of thesub-carriers as between the square QAM constellation and the non-squareQAM constellation.
 44. The method of claim 42, wherein the non-squareQAM constellation is selected from the group consisting of 128, 512 QAMconstellations and a 2048 QAM constellation.
 45. The method of claim 44,wherein the square QAM constellation is selected from the groupconsisting of 16, 64, 256, 1024 QAM constellations and a 4096 QAMconstellation.
 46. The method of claim 42, wherein demapping includesdetermining a least likelihood ratio for demodulated sub-carriers.
 47. Anon-transitory computer-readable medium comprising instructions storedthereon, that if executed by a processor, cause the processor to: removea cyclic prefix (CP) and to perform a reverse windowing operation ontime domain constellation symbols of mixed-modulation data sub-carriers,wherein the data sub-carriers include Orthogonal Frequency DivisionMultiplexing (OFDM) sub-carriers and are modulated based on QuadratureAmplitude Modulation (QAM) constellations including a square QAMconstellation and a non-square QAM constellation; transform theconstellation symbols from time domain symbols to frequency domainsymbols; de-interleave the constellation symbols in time and frequency;demodulate the sub-carriers; and use a constellation demapper to demapthe sub-carriers.
 48. The computer-readable medium of claim 47, whereindemapping includes demapping unequal numbers of the sub-carriers asbetween the square QAM constellation and the non-square QAMconstellation.
 49. The computer-readable medium of claim 47, wherein thenon-square QAM constellation is selected from the group consisting of128, 512 QAM constellations and a 2048 QAM constellation.
 50. Thecomputer-readable medium of claim 49, wherein the square QAMconstellation is selected from the group consisting of 16, 64, 256, 1024QAM constellations and a 4096 QAM constellation.
 51. Thecomputer-readable medium of claim 47, wherein demapping includesdetermining a least likelihood ratio for demodulated sub-carriers.